Uniaxial counter-propagating monolaser atom trap

What is claimed is: 1. A uniaxial counter-propagating monolaser atom trap for cooling and trapping atoms with a single a laser beam, the uniaxial counter-propagating monolaser atom trap comprising: an atom source that provides primary atoms, such that the primary atoms move in an atom primary direction; a light source opposing the atom source and that produces primary light, the primary light propagating in a light primary direction, the light primary direction opposing the atom primary direction such that the primary light counter-propagates relative to the primary atoms; an atom slower interposed between the atom source and the light source and that: receives the primary atoms from the atom source; receives the primary light as slowing light; subjects the primary atoms to the slowing light; and slows the primary atoms to form slowed atoms from the primary atoms in response to interaction of the primary atoms with the slowing light, the slowed atoms moving in the atom primary direction; an optical diffractor interposed between the atom slower and the light source and comprising: a diffraction surface opposing the light source; a slower surface opposing the atom source; an atom transfer wall that bounds an atom transfer aperture; the atom transfer aperture that communicates the slowed atoms to a trapping region from the atom slower and communicates the primary light to the atom slower from the trapping region; a plurality of diffraction gratings disposed on the diffraction surface and comprising: a first diffraction grating that receives the primary light from the light source and produces first reflected light from the primary light, the first reflected light moving in a first light reflection direction; a second diffraction grating that receives the primary light from the light source and produces second reflected light from the primary light, the second reflected light moving in a second light reflection direction; and a third diffraction grating that receives the primary light from the light source and produces third reflected light from the primary light, the third reflected light moving in a third light reflection direction; the trapping region interposed between the optical diffractor and the light source and that: receives the first reflected light, the second reflected light, and the third reflected light such that the first reflected light, the second reflected light, and the third reflected light intersect in a reflected light intersection volume in the trapping region to form trap light from the first reflected light, the second reflected light, and the third reflected light; receives the slowed atoms in the trap light; and produces trapped atoms from the slowed atoms in response to subjecting the slowed atoms to the trap light. 2. The uniaxial counter-propagating monolaser atom trap of claim 1 , further comprising: a flow tube disposed on the slower surface and opposing the atom source and that receives the slowed atoms from the atom slower and communicates the slowed atoms from the atom slower to the trapping region through the atom transfer aperture. 3. The uniaxial counter-propagating monolaser atom trap of claim wherein the trapping region further comprises a magneto-optical trap. 4. The uniaxial counter-propagating monolaser atom trap of claim 1 , wherein the atom slower comprises a Zeeman slower. 5. The uniaxial counter-propagating monolaser atom trap of claim 1 , wherein the atom slower comprises a slower member interposed between the atom source and the optical diffractor. 6. The uniaxial counter-propagating monolaser atom trap of claim 5 , wherein the slower member comprises magnetic field coils, a permanent magnet, a voltage electrode, or a combination comprising at least one of the foregoing slower members. 7. The uniaxial counter-propagating monolaser atom trap of claim 6 , wherein the slower member is the magnetic field cons that produces a spherical magnetic quadrupole field. 8. The uniaxial counter-propagating monolaser atom trap of claim 1 , wherein the first diffraction grating comprises a first set of linear grating lines; the second diffraction grating comprises a second set of linear grating lines; and the third diffraction grating comprises a third set of linear grating lines. 9. The uniaxial counter-propagating monolaser atom trap of claim 8 , wherein the first set of linear grating lines, the second set of linear grating lines, and the third set of linear grating lines are arranged on the diffraction surface in three truncated triangles, wherein the atom transfer aperture is centrally disposed among the three truncated triangles. 10. The uniaxial counter-propagating monolayer atom trap of claim 1 , further comprising a shutter interposed between the atom source and the atom slower and that interrupts communication of the primary atoms from the atom source to the atom slower. 11. The uniaxial counter-propagating monolayer atom trap of claim 1 , further comprising a vacuum chamber in which are disposed the atom slower, the optical diffractor, and the trapping region. 12. The uniaxial counter-propagating monolaser atom trap of claim 1 , further comprising: a first permanent magnet interposed between the optical diffractor and the light source and that provides an axial magnetic field directed along the light primary direction; and a second permanent magnet interposed between the optical diffractor and the light source and that provides a two-dimensional magnetic field gradient along the light primary direction. 13. The uniaxial counter-propagating monolaser atom trap of claim 12 , wherein the optical diffractor further comprises a fourth diffraction grating that receives the primary light from the light source and produces fourth reflected light from the primary light, the fourth reflected light moving in a fourth light reflection direction. 14. The uniaxial counter-propagating monolaser atom trap of claim 1 , wherein the light source produces a first primary light and a second primary light that are combined in primary light, wherein the second primary light comprises a frequency that is chirped for slowing the primary atoms. 15. An optical diffractor for cooling and trapping atoms with a single a laser beam, the optical diffractor comprising: a diffraction surface; a slower surface on a side of the optical diffractor opposite the diffraction surface; an atom transfer wall that bounds an atom transfer aperture; the atom transfer aperture that communicates slowed atoms to a trapping region from an atom slower and communicates primary light to the atom slower from the trapping region; a plurality of diffraction gratings disposed on the diffraction surface and comprising: a first diffraction grating that receives the primary light from a light source and produces first reflected light from the primary light, the first reflected light moving in a first light reflection direction; a second diffraction grating that receives the primary light from the light source and produces second reflected light from the primary light, the second reflected light moving in a second light reflection direction; and a third diffraction grating that receives the primary light from the light source and produces third reflected light from the primary light, the third reflected light moving in a third light reflection direction, wherein the diffraction gratings reflects the primary light as the first reflected light, the second reflected light, and the third reflected light respectively along the first light reflection direction, the second light reflection direction, a